Device for transporting parts for supplying machines

ABSTRACT

A device for transporting parts ( 1 ) includes a transporting member ( 3 ) whereon the parts to be transported ( 2 ) are to be arranged. The transporting member ( 3 ) is mounted mobile relative to a frame ( 9 ) of the device for reciprocating movement, which occurs in a plane (P) in which the parts are transported. A driving device comprises at least a drive cam ( 4 ) co-operating with at least a roller that is displaced with the transporting member, so that the movement in the plane is a reciprocating translational movement generated by the rotation of the drive cam ( 4 ).

The present invention concerns a device for transporting parts for supplying machines intended to permit supply of machine parts, or in general intended to ensure all types of parts transport in the industrial process.

At the present time, several kinds of appliances are known which are intended for the transport of parts and notably devices intended for the supply of machines, the most recent of which are the conveyor belt devices formed by a belt or a band driven by rollers or by vibrating rail type devices generally called vibratory type devices.

The conveyor belt devices present drawbacks with respect to occupation of space and installation is therefore not possible in a great number of situations. They also present certain drawbacks strictly connected with the piecemeal supply of parts, in other words, with the transition which takes place at the end of the band between the conveyor belt and the supplied machine.

The vibratory devices operate on a relatively simple principle which consists of alternatively displacing the rail axially while separating the transported pieces in the air pending return of the rail to its former position. Thus, these vibratory units present oscillating movements with a vertical component destined to cause separation of pieces and horizontal components by axial displacement of the rail. In said manner, the pieces remain in contact with the rail only during its axial displacement towards the front. These vibratory rails, however, present numerous drawbacks related to their design and their utilization. In fact, they do not permit transport of parts at rapid rates and are therefore limited to certain applications. Moreover, certain parts to be transported are fragile and are therefore susceptible to being damaged during their displacement along the rail by repeated shocks due to the vertical oscillations of said rail. In addition, certain pieces can no longer be transported by such rails by reason of their shape. In fact, very fine pieces will overlap and become jammed during the course of their travel; moreover, very heavy pieces require powerful vibratory units, which would interfere with the operation of the rest of the machine. Also, these vibrating rail appliances present the disadvantage of being able to transport the pieces in only one direction, in contrast to the conveyor belt devices, and they also present problems in exiting from rail with certain parts possibly being encountered in the overhang with the risk of being damaged by longitudinal rail end deflection.

Consequently, it is the objective of the present invention to resolve the aforementioned drawbacks of parts supply devices with the aid of simple, reliable means which are not expensive and which are easily implemented. The invention proposes a parts supply device which permits rapid transport of parts, which tends to function in both directions, which is capable of transporting fragile pieces and light-weight parts, while occupying little space, and which facilitates its adaptation to different situations encountered in the industrial process.

According to its principal characteristic, the device for transporting parts is of the type which comprises a transporting member on which the parts to be transported are intended to be arranged, said transporting member being mounted mobile relative to the frame of the device, to be at least imparted a recipocrating movement which occurs in the plane in which the parts are transported, by a driving device, and which is characterized in that the driving device comprises at least a drive cam, co-operating at least with a roller, which is an integral part of the transporting member, to provide same with its movement.

According to a preferred embodiment of the device for transporting parts according to the invention, the transporting member is a longitudinal rail whose movement in the plane of displacement of the parts is a reciprocating translational movement, generated by the rotation of the drive cam.

According to another embodiment of the device for transporting parts according to the invention, the transporting member is a rail having a round shape, either circular or spiral, whose movement in the plane of displacement of parts is a reciprocating translational movement generated by the rotation of the drive cam.

According to a complementary characteristic of the device for transporting parts according to the invention, it is characterized in that the transporting member is carried by a rail support which carries a roller which drives the parts in translational movement according to the longitudinal displacement axis when it co-operates with the rotary cam.

According to another characteristic of the device for transporting parts according to the invention, same is characterized in that it comprises a motorized device which drives the cam to rotate around its axis of revolution, said rotation of the cam provoking, thanks to the specific shape of its contact surface, the alterative longitudinal displacement of the rail support by co-operating with the roller.

According to the preferred embodiment of the device for transporting parts, the axis of rotation of the cam and the axis of rotation of the drive roller are parallel.

According to another characteristic of the device for transporting parts according to the invention, it is characterized in that the cam presents an involute rounded surface which comprises a first zone called acceleration zone, which is very short, then a zone called advancement zone, where the radius of the cam increases in constant manner over its angular sector, it then comprises a brief deceleration zone, in front of a zone called ‘draw-back’, where the radius decreases.

According to a complementary characteristic of the device for transporting parts, the forward movement of the rail corresponding to the acceleration zone, the forward movement zone and deceleration zone of the involute surface represents an angular sector of the cam comprising between 200° and 300° whereas the zone called the ‘draw-back’ zone represents an angular sector comprising between 60° and 160°.

According to an embodiment of the device for transporting parts according to the invention, when the cam travels one complete turn, the roller and thus the rail undergo a forward movement corresponding to the acceleration zone, the forward movement zone and the deceleration zone of the cam during approximately two thirds of turn, then a very abrupt ‘draw-back’ movement during the last third of the turn, said movement of the rail permitting—thanks to the acceleration zone—rapid adjustment of the rail to the relative parts displacement rate (in regard to the frame) and to accelerate same again before moving at a constant rate during the forward movement zone, and to then let them slide during the breaking or deceleration zone, followed by the rail ‘draw-back’ which takes place quickly before commencement of another cycle.

According to a complementary characteristic of the device for transporting parts, the rotary cam is controlled by a motorized device which permits its rotation in both directions according to the user's choice.

According to another embodiment, the cam is sandwiched between two rollers, while said cam is composed of two superposed cams, a first cam or upper cam, with which a first roller (6 a) cooperates, and a second cam or lower cam, with which a second roller co-operates.

Other characteristics and benefits of the invention are apparent from the description which follows in regard to the attached drawings, which are provided by way of example only and are not limited thereto.

FIGS. 1 to 6 depict a first embodiment of the device for transporting parts according to the invention.

FIG. 1 represents the device in perspective.

FIG. 2 a represents the device in lateral view.

FIG. 2 b illustrates the device for transporting parts in frontal view.

FIG. 3 represents an exploded view of the transport device.

FIG. 4 presents a sectional view of the rail mechanism.

FIG. 5 illustrates the pivoting cam, viewed from below.

FIG. 6 shows a schematic representation of the contact surface of the cam.

FIGS. 7 to 10 illustrate a second embodiment.

FIG. 7 is a perspective view similar to FIG. 3.

FIG. 8 is a lateral sectional view.

FIG. 9 is an illustration seen from above, depicting the cams and the rollers.

FIG. 10 is a perspective view showing the cams and the rollers.

The invention concerns a device for transporting parts, bearing the general reference identification (1), said device is intended for transporting parts (2) to supply a machine tool or other appliance within the framework of an industrial process. It comprises a transporting member (3) on which the parts to be transported (2) are arranged, said member being destined to put into movement the parts in the plane (P) in which they are located so as to displace them relative to said member.

According to the invention, the transporting member is mobile relative to the frame of the device to be put into motion in the plane (P) by a driving device (DE) comprising at least one cam (4). The movement of the transporting member (3) occurs only in the plane (P) in which the parts (2) are displaced. Thus, the parts (2) are displaced on the transporting member (3) by sliding at the moment when said member moves.

According to the first embodiment of the device for transporting parts (1) according to the invention and as indicated in FIGS. 1 to 5, the transporting member (3) is beneficially composed of a longitudinal rail whose movement in the plane (P) is a reciprocating translational movement generated by the rotation of the drive cam (4). Said reciprocating translational movement of the rail (3) provokes the displacement by means of sliding of parts (2) along the rail thanks to the particular configuration of the mechanical parameters (acceleration, speed) of the alternative movement, obtained thanks to the drive cam (4) and the physical parameters of the constitutive elements (friction coefficient). It should be noted that such device could utilize a different transporting member energized by another type of movement.

Thus, according to a non-represented embodiment, the movement of the transporting member is a movement of alternative rotation. It is accordingly beneficially composed of a rail having round, circular or spiral shape, which is energized by rotational alternative movement of reduced amplitude, said movement being generated by the rotation of a drive cam similar to that of the first embodiment, which co-operates with an incline which is an integral part of a circular rail support hinged around a fixed axis.

According to the first embodiment of the device for transporting parts (1), the transporting rail (3) on which are arranged the parts to be transported (2) is carried by a rail support (5) which carries a roller (6). Said roller (6) is installed on the support (5) so as to be able to drive in translation according to the longitudinal axis (XX′) when it cooperates with the rotating cam (4) as is indicated in FIGS. 1, 3 and 4.

The device for transporting parts (1) comprises a motorized device (7) which drives the cam (4) to rotate around its axis of revolution (YY′). The rotation of the cam (4) provokes—thanks to its specific shape—the alternative longitudinal displacement of the rail support (5) while cooperating with the roller (6). It should be noted that the axes of rotation of the can and the roller are parallel, thus reducing wear and tear due to friction at time of their cooperation.

It goes without saying that the device could present a different configuration with respect to cooperation of the cam and the rail support. The axis of rotation of the cam could be positioned differently, while the latter would operate on a sloping plane of the support and no longer on a roller, for example.

According to the embodiment illustrated in FIG. 1 to 6 of the supply device of parts (1), said device comprises compensation means intended to act upon the roller (6) in order to maintain permanent contact with the cam (4) so that the alternative movement of the rail (3) corresponds exactly to the involute curve of the surface in contact with the came (4). These compensation means can be of several kinds, such as formed by a traction spring (8). It should be noted that this spring (8) can act directly between the frame (9) on which the motor (7) is fixed and the rail (3), while the rail support (5) is mounted in sliding fashion on a guide (10) of the frame in order to be able to act on the cam (4) via intermediary of the transporting rail (3) and the spring (8). It should be noted that the cooperation of the rail support (5) with the guide (10) could be realized very simply by two lateral flexible sheets which would secure the connection between the frame (9) and the vibrating rail (3).

The device for supply of parts (1) according to the invention, the rail (3) is mounted in sliding fashion on the frame (9) via intermediary of its support (5) and guide (10). Its movement in the plane is a translational movement, the accelerations and slow-downs of which are exclusively controlled by the slope of the external surface or the contact surface of the drive cam (4).

According to the illustrated embodiment, the drive cam (4) presents an involute surface curve such as is illustrated in FIG. 6. Starting from point 0, it comprises a first zone (A) called acceleration zone, which is very short, representing an angular segment of less than 20°, followed by a forward movement zone (B) in which the rail (3) moves at constant speed, with the radius of the drive cam increasing in somewhat constant fashion over an angular segment approximately equal to 220°, in a manner so that the rail moves with low to zero acceleration. It then comprises a short deceleration zone (C), the angular segment of which is less than 20°, in front of a zone called “recoil” or “draw-back” zone (D)—a draw-back, which occurs which strong acceleration during the first half of the angular segment (D1), and with some slowing down in a second portion (D2), before returning to the initial point of the drive cam. It can thus be stated that the forward movement of the rail corresponding to zones (A, B,C) represents an angular segment of the drive cam ranging between 200° and 300°, whereas the “draw-back zone (D) comprises between 60 ° and 160°. According to the preferred embodiment of the transporting device, the group of zones (A, B, C) represent an angular segment of more than 240°.

When the drive cam travels one complete turn, the roller (6) and the rail (3) undergo movement in forward direction corresponding to zones (A, B, C,) of the drive cam during approximately two thirds of the turn, then a more rapid draw-back movement during the last third of the turn. Said movement of the rail permits,—thanks to the acceleration zone (A)—rapid attainment of relative movement rate (with respect to the frame) of parts (2) and to again accelerate before moving at constant speed during the deceleration zone (C), then the draw-back (zone D) of the rail which occurs quickly before restarting the cycle. It should be noted that the slopes of the contact surface of the drive cam are specifically calculated so that when the rail (3) retreats, which occurs quite suddenly, the parts (2) continue to move forward at relative speed with respect to the frame, prior to being recovered by the rail in the acceleration zone (A) at the moment when it attains their speed.

It should be noted, as indicated in FIG. 5, that the drive cam has holes for passage of pins, said pins permitting the exact placement of said drive cam on the machine tool with exact and reproducible positioning of the reference line or point 0 of the drive cam. Said drive cam can, furthermore, be installed on the motorized device, in detachable fashion, in order to be interchangeable, thus permitting, for example, the adaptation of the transporting device to different pieces and to different constraints of the machines to be supplied.

FIGS. 7 to 10 represent a second specific embodiment of the invention.

With respect to this second embodiment, for reasons of clarity, identical reference numbers have been designated for the same elements as were used in the first embodiment and when viewing the figures for the second embodiment the reader can readily refer to the description given for the first specific embodiment.

According to said embodiment, the compensation means of the first specific embodiment, intended to maintain the roller (6) in contact with the drive cam (4) and constituted by spring (8), have been replaced by a structure of two rollers (6 a, 6 b) and two cams (4 a, 4 b).

Accordingly, the cam (4) is composed of two superposed cams. In other words, a first cam or upper cam (4 a) and a second cam or lower cam (4 b). The two cams (4 a and 4 b) are integral and mounted on the motor exit shaft (7).

Furthermore, the rail support (5) carries two rollers (6 a, 6 b) intended to cooperate with the cams (4 a, 4 b). In other words, a first roller (6 a) which cooperates with the first cam (4 a) and a second roller (6 b) which cooperates with the second cam (4 b). Consequently, the two rollers are arranged on both sides of the two cams and plane P going through the center of the rollers passes through the pivoting axis (Y, Y′) of the two cams. The general horizontal plane (H1) of the first roller is arranged in the general horizontal plane of the first cam, while the general horizontal plane (H2) of the second roller is arranged in the general horizontal plane of the second cam. The general horizontal plane (HI) of the first roller and thus the general horizontal plane of the first cam is located above the general horizontal plane (H2) of the second roller and thus the general horizontal plane of the second cam.

It is therefore obvious that the 2-cam unit is sandwiched between the two rollers, which permits assurance of displacement in two directions of the rail support without spring system as provided in the first specific embodiment. Thanks to the two-roller device, acceleration is controlled and the inertia of the moving parts has no detrimental effect. And this [occurs] without interfering friction, which can produce a somewhat stiff spring.

In addition, it should be noted that the motoried device which permits turning of the cam can beneficially function in both directions. Thus, when the drive cam turns in one direction, the parts move forward, whereas reversal of the direction of rotation of the cam brings about retreat of the parts. It should also be noted that the motorized device can beneficially permit regulation of the speed of rotation of the cam.

It should likewise be noted that the rail can be covered with a facing, the friction coefficient of which is adapted to the range of parts it is intended to transport.

Needless to say, the invention is not limited to the specific embodiment, described and presented by way of example, but it also includes all equivalent techniques as well as combinations thereof. 

1. A device for transporting parts comprising: a transporting member on which the parts are transported, said transporting member being movably mounted relative to a frame of the device for reciprocating movement along a plane, in which the parts are transported; a driving device for driving the transporting member with the reciprocating movement, the driving device including: at least one drive cam, at least one roller mounted to the transporting member and cooperating with the drive cam, so that the movement in the plane is a reciprocating translational movement generated by the rotation of the drive cam.
 2. The device for transporting parts according to claim 1, wherein the drive cam has a non-constant radius and further including: a compensating means for causing the roller to maintain contact with the cam.
 3. The device for transporting parts according to claim 1, wherein the transporting member includes a rail of curved shape, circular or spiral, whose movement in the plane is a movement of alternative rotation generated by rotation of the drive cam.
 4. The device for transporting parts according to claim 1, wherein the transporting member is carried by a rail support which carries the roller which drives the rail support in translation along a longitudinal axis when the roller cooperates with the rotary cam.
 5. The device for transporting parts according to claim 4, wherein the driving device further includes: a motorized device which drives the cam to rotate around an axis of revolution, said rotation of the cam causing the reciprocating translational movement of the rail support and the roller along the longitudinal axis.
 6. The device for transporting parts according to claim 5, wherein the axis of rotation of the cam and an axis of rotation of the drive roller are parallel.
 7. The device for transporting parts according to claim 1, wherein the cam presents an involute surface curve which comprises: a short acceleration zone, then an advancement zone in which a radius of the cam increases in constant fashion over its angular segment, then a short deceleration zone, and a draw-back-zone in which the radius diminishes.
 8. The device for transporting parts according to claim 7, wherein the transporting member moves forward when the roller contacts the acceleration, advancement, and deceleration zones, which zones span an angular segment of the cam ranging between 200° and 300° and the draw-back zone spans an angular segment ranging between 60° and 160°.
 9. The device for transporting parts according to claim 7, wherein when the cam travels one full turn, the roller and thus the transporting member undergo a forward movement from an initial position corresponding to the acceleration, advancement, and deceleration zones of the cam, during approximately two thirds of the turn, then a more abrupt reverse movement corresponding to the draw-back zone during the last third of the turn, during the acceleration zone accelerating the parts to a displacement speed, advancing the parts constantly at the displacement speed during the advancement zone, and allowing the parts to slide during the deceleration zone (C), then the draw-back zone quickly returns the transport member to the initial position to re-start the cycle.
 10. The device for transporting parts according to claim 1, further including: a motorized device which rotates the cam in one direction to move the parts forward along the transport member, and rotates the cam in an opposite direction to move the parts rearward along the transport member.
 11. The device for transporting parts according to claim 1, wherein the cam is sandwiched between two rollers.
 12. The device for transporting parts according to claim 11, wherein the cam is composed of two superposed cams, an upper cam with which cooperates a first of the two rollers and a lower cam which cooperates a second of the two rollers.
 13. A reciprocating feeder for transporting parts, the reciprocating feeder comprising: a longitudinally elongated transport member; a mounting structure for mounting the transporting member on a frame for longitudinal reciprocating motion; at least one roller mounted for longitudinal movement with the transporting member; an eccentric cam mounted on a rotary drive which is connected with the frame, the cam being mounted to engage the roller and urge the roller along one direction of the longitudinal reciprocating movement; a compensating means for maintaining the roller in contact with the eccentric cam and moving the transporting member in an opposite direction along the longitudinal reciprocating movement.
 14. The feeder according to claim 13, wherein the eccentric cam drives the roller and reciprocating member in one of the first and second directions over at least 200° of rotation and less than 300° of rotation and allows the compensating means to move the roller and reciprocating member in the other of the first and second directions for between 60° and 160° of cam rotation.
 15. The feeder according to claim 13, wherein the compensating means includes one of a spring, a second roller, and a second roller and cam assembly.
 16. A method for transporting parts on a transporting member which is movably mounted for reciprocating movement relative to a frame along a plane in which the parts are to be transported, the method comprising: rotating an eccentric cam which engages at least one roller that is connected with the transporting member for displacement therewith; through co-operating interaction between the cam and the roller, causing a reciprocating translational movement in the plane of the transporting member. 